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Topic: HFE-related Hereditary Hemochromatosis Summary: HFE Hereditary Hemochromatosis (HFE-HH) is the most common and best-described form of iron overload disorder worldwide. The major HFE gene mutation identified in Caucasians is C282Y. Not all individuals with a genetic predisposition to HH will go on to develop high serum ferritin or iron overload. Therapeutic phlebotomy (when necessary) can prevent life-threatening complications such as cirrhosis. Iron overload can be completely prevented in asymptomatic individuals with a genetic predisposition. Bottom line: Patients should be offered genetic counselling/testing if they have elevated serum ferritin and transferrin saturation, signs or symptoms suggestive of iron-overload disorder, or a first-degree relative with HFE hemochromatosis. The Disease HFE Hereditary Hemochromatosis (HFE-HH) is one of the most common autosomal recessive disorders in Caucasians. Iron overload from HFE-HH can sometimes lead to permanent liver, pancreatic and cardiac damage. There are less common forms of HH due to other genes such as HJV, HAMP, and TFR2. About 4-5 per 1000 individuals of northern European ancestry are genetically susceptible to HFE-HH, but fewer individuals actually develop the disease.1,2 Cause: very high absorption of iron in the duodenum results in excessive storage of iron in the liver, skin, pancreas, heart, joints, and pituitary. Symptoms: Abdominal pain, weakness, lethargy, and weight loss are early symptoms. Without therapy, males most commonly develop symptoms between 40 and 60 years of age (range 20s to 70s) and females after menopause. Liver Disease: Early signs and symptoms of liver involvement include right upper quadrant pain and hepatomegaly. Hepatic fibrosis or cirrhosis may occur after the age of 40, and may eventually lead to hepatocellular carcinoma. Other findings in untreated individuals may include progressive skin pigmentation (“bronzing”), type 2 diabetes mellitus, congestive heart failure and/or arrhythmias, arthritis, and hypogonadism. Suspect HH in individuals with elevated transferrin saturation and elevated serum ferritin. Surveillance: Routine iron studies (transferrin saturation and ferritin). Treatment: removal of excess iron by phlebotomy– cheap and very effective. Note that initiation of phlebotomy is indicated when serum ferritin is >1000µg/L; more moderate elevations may require clinical judgment.3 Dietary management of individuals with HH includes avoidance of iron supplements, iron-containing cooking pots/pans, excess vitamin C, and uncooked shellfish (due to potential infection with Vibrio vulnificus). Those with hepatic involvement are advised to avoid alcohol consumption. The Gene The HFE gene, on chromosome 6, makes a cell-surface protein that binds transferrin and plays a role in iron absorption. The two common mutations are called C282Y and H63D. The frequency of C282Y in a population of European descent is 6.2% but ranges from 12.5% in Ireland to 0% in Southern Europe.2 H63D may modify iron levels but is unlikely to cause iron overload in the absence of C282Y.4 Consequences of having one or two faulty HFE genes One faulty gene → unaffected carrier Carriers are NOT expected to develop clinical findings of iron overload because their “normal” copy of the HFE gene (located on their other chromosome 6) compensates. Double dose of the faulty gene → tendency to iron overload Most individuals with iron overload caused by hereditary hemochromatosis have two copies of the C282Y mutation. Individuals with one copy of C282Y and one of H63D may have high iron indices in middle age but iron-overload related disease is uncommon in this group.5 Men who have two copies of the C282Y mutation are much more likely to develop disease related to iron overload than women with the same genotype. A woman’s risk is moderated by iron loss during menstruation, with overload only occurring later in life. Many individuals with two HFE mutations will not express the disease (the penetrance is low, especially in females). There are emerging reports of HFE genotypes in association with increased risks for diseases such as breast and colorectal cancer,6 heart disease in women7 and other disease endpoints.8 Further validation of these associations is required. Who should consider genetic counselling/testing? Adult patients with a first degree relative with hemochromatosis o Family studies should be performed stepwise to minimize unnecessary testing. o There is a 25% risk for the sibs of an affected individual to be affected. o Note: All offspring of an affected individual will have at least one faulty HFE gene. Spouses should generally be offered testing before offspring. DNA testing of young children is generally not indicated. Individuals with biochemical evidence of iron overload i.e. elevated transferrin saturation and ferritin Individuals with clinical features suggestive of HH such as unexplained hepatomegaly or elevated liver enzymes; or early-onset type 2 diabetes, heart disease, sexual dysfunction or arthralgia. Look out for other causes of iron overload (e.g. excess alcohol use, unrelated liver disease). Testing - for the faulty gene If you suspect HH, check fasting serum transferrin saturation (most sensitive test) and serum ferritin. Adults with serum transferrin saturation >45% warrant genetic testing. Ferritin >200 mcg/L in premenopausal women and >300 mcg/L in postmenopausal women or men indicates possible iron overload. Note: ferritin is an acute phase reactant and can be elevated for other reasons such as inflammation and malignancy. Thus, an elevated serum ferritin should be followed by other tests before the diagnosis of hemochromatosis is made. Population-based screening is not recommended. Once the gene change is found in a person, his/her parents, siblings and adult children should be offered testing. The spouse could also be tested if the couple has younger children. For information about ordering genetic testing for HFE, contact your local genetics clinic. Benefits of genetic testing Clarification of diagnosis Identification of asymptomatic individuals at risk of HFE-HH early enough to prevent end organ damage for this readily treatable condition. Harms/limitations of genetic testing Labeling a healthy person with a “disease” (just because they have altered genes, ascertained through an affected relative) when they may never manifest the symptoms of this “disease.” Insurance concerns. Potential to reveal non-paternity (e.g., if a child of an affected parent tests negative as a carrier). Genetic testing for HFE-HH has not been reported to be associated with negative psychosocial consequences.9 Web Resources: www.geneclinics.org Canadian Hemochromatosis Society: http://www.cdnhemochromatosis.ca/ Centre for Disease Control http://www.cdc.gov/ncbddd/hemochromatosis/index.htm References: 1. McLaren GD, Gordeuk VR. Hereditary hemochromatosis: insights from the Hemochromatosis and Iron Overload Screening (HEIRS) Study. Hematology Am Soc Hematol Educ Program. 2009:195-206. 2. European Association For the Study Of The Liver. EASL clinical practice guidelines for HFE hemochromatosis. J Hepatol. 2010;53:3-22. 3. Adams, PC & Barton, JC. How I treat hemochromatosis. Blood 2010;116(3):317-325. 4. Olynyk JK, Trinder D, Ramm GA, Britton RS, Bacon BR. Hereditary Hemochromatosis in the Post-HFE Era. Hepatology 2008; 48(3):991-1001. 5. Gurrin LC, Bertalli NA, Dalton GW, et al. HFE C282Y/H63D Compound Heterozygotes Are at Low Risk of Hemochromatosis-Related Morbidity. Hepatology 2009; 50(1):94-101. 6. Osborne NJ, Gurrin LC, Allen KJ, et al. HFE C282Y homozygotes are at increased risk of breast and colorectal cancer. Hepatology 2010 Apr;51(4):1311-8. 7. Pardo Silva MC, Njajou OT, Alizadeh BZ, et al. HFE gene mutations increase the risk of coronary heart disease in women. Eur J Epidemiol. 2010 Sep;25(9):643-9. 8. Ellervik C, Birgens H, Tybjaerg-Hansen A, Nordestgaard BG. Hemochromatosis genotypes and risk of 31 disease endpoints: meta-analyses including 66,000 cases and 226,000 controls. Hepatology 2007 Oct;46(4):1071-80. 9. Picot J, Bryant J, Cooper K, et al. Psychosocial Aspects of DNA Testing for Hereditary Hemochromatosis in At-Risk Individuals: A Systematic Review. Genet. Test. Mol. Bioma. 2009:13(1) 7-14. “Gene Messenger” is for educational purposes only and should not be used as a substitute for clinical judgement. The “GenetiKit” team aims to aid the practicing clinician by providing informed opinions regarding genetic services that have been developed in a rigorous and evidence -based manner. Physicians must use their own clinical judgement in addition to published articles and the information presented herein. The members of the GenetiKit research team assume no responsibility or liability resulting from the use of information contained on “Gene Messenger.” Updated November 2010 Funding provided by CIHR Dr Carroll is Principal Investigator of the GenetiKit Project and is the Sydney G Frankfort Chair in Family Medicine at Mount Sinai Hospital and an Associate Professor in the Department of Family Medicine at the University of Toronto. In alphabetical order, other members of the GenetiKit Team are as follows: Dr Allanson is Chief of the Department of Genetics at the Children's Hospital of Eastern Ontario (CHEO) in Ottawa, Ontario and Full Professor in the Department of Pediatrics at the University of Ottawa. Dr Blaine is an Assistant Professor in the Department of Family and Community Medicine at the University of Toronto in Ontario and Lead Physician of the STAR Family Health Team in Stratford, Ontario. Ms Cremin is a Clinical Assistant Professor in the Department of Medical Genetics, University of British Columbia. Ms Dorman is a Genetic Counselor at the Sudbury Regional Hospital in Ontario. Ms Gibbons is a Genetic Counselor at the North York General Hospital in Ontario. Dr Graham is Vice-President of Knowledge Translation, Canadian Institutes of Health Research. Dr Grimshaw is a Professor in the Department of Medicine and Director of the Clinical Epidemiology Program at the Ottawa Health Research Institute. Ms Honeywell is an Assistant Professor in the Department of Pediatrics at the University of Ottawa and in the CHEO Departments of Genetics and Cardiology. Dr Meschino is a Clinical Geneticist at North York General Hospital and Assistant Professor in the Department of Paediatrics at the University of Toronto. Ms Permaul is a Research Associate in the Granovsky Gluskin Family Medicine Centre at Mount Sinai Hospital. Dr Wilson is an Associate Professor in the Department of Epidemiology and Community Medicine at the University of Ottawa.